CN113228531B

CN113228531B - Far field wireless power transfer using local fields with multi-tone signals

Info

Publication number: CN113228531B
Application number: CN202080005435.9A
Authority: CN
Inventors: 杨松楠; 潘宁
Original assignee: Huawei Digital Power Technologies Co Ltd
Current assignee: Huawei Digital Power Technologies Co Ltd
Priority date: 2019-04-09
Filing date: 2020-04-08
Publication date: 2023-03-24
Anticipated expiration: 2040-04-08
Also published as: US20220029462A1; EP3921952A1; CN113228531A; WO2020210283A1

Abstract

Techniques and apparatus for a far-field wireless power transmitter are described. Far-field wireless power transmitters use beamforming to locate power signals transmitted from an array of antennas. Multi-tone signals are used for power signals, wherein the signal transmitted from each of the antennas is formed by a plurality of tones having a frequency center and being spaced by a uniform frequency difference, and relative delays and/or relative amplitude differences are introduced into the signals from different antennas of the array, such that a beam is formed in the area where the antennas of the far-field wireless power receiver are located. By using two such transmitters placed on either side of the receiver, a hot spot for multi-tone power signals can be formed in the area of the antenna of the receiver, while having lower field values away from this area.

Description

Far field wireless power transfer using local fields with multi-tone signals

Cross Reference to Related Applications

This application claims priority from U.S. provisional application No. 62/831,570 entitled "METHOD TO CREATE LOCALIZED FIELD WITH MULTI-TONE SIGNALS IN FARFIELD WIRELESS POWER TRANSFER" filed 2019, 4, 9, month, 4, the entire contents of which are incorporated herein by reference.

Technical Field

The present disclosure relates generally to wireless power transfer systems and methods of use thereof.

Background

Wireless Power Transfer (WPT) has many applications in battery charging and powering various electronic devices. Most current wireless charging or power transfer systems are near-field systems that rely on transferring power through magnetic coupling of a coil on a power transmitter and a coil on a power receiver. Practical far-field wireless power transfer techniques would be very useful as this would enable a Wi-Fi like user experience to power and charge the device. However, a significant disadvantage of current far-field wireless power transfer methods is that when they transmit energy from the transmitter to the receiver by generating a field or vibration at the receiver location, strong fields are also generated along the path between the transmitter and the receiver. This field is typically stronger than the field at the receiver location, which creates safety and interference issues.

Disclosure of Invention

According to a first aspect of the present disclosure, a wireless power transmitter includes a beamformer and a first array of a plurality of antennas. The beamformer is configured to: generating a multi-tone power signal formed from a plurality of tones having frequency centers and spaced by a uniform frequency difference and generating a first plurality of multi-tone power signals from the multi-tone power signal, the first plurality of multi-tone power signals configured to form a beam at a first location. A first array of the plurality of antennas is connected to the beamformer, each of the antennas in the first array being configured to receive and transmit one of a first plurality of multi-tone power signals.

Optionally, in the second aspect and further aspects of the first aspect, each of the first plurality of multi-tone power signals has a corresponding relative phase difference configured to form a beam at the first location.

Optionally, in a further aspect of the third and second aspects, each of the first plurality of multi-tone power signals has a corresponding relative amplitude difference configured to form a beam at the first location.

Optionally, in the fourth and further aspects of the third aspect, the one or more control circuits are connected to the beamformer and configured to determine corresponding relative phase differences and relative amplitude differences for the first plurality of multi-tone power signals.

Optionally, in a further aspect of the fifth and fourth aspects, the wireless power transmitter further comprises a communication antenna connected to the one or more control circuits, the one or more control circuits further configured to exchange signals with the wireless power receiver through the communication antenna and determine corresponding delay relative phase differences and relative amplitude differences for the first plurality of multi-tone power signals based on the signals exchanged with the wireless power receiver.

Optionally, in further aspects of the sixth and fifth aspects, the one or more control circuits are further configured to determine corresponding relative phase differences and relative amplitude differences based on signals exchanged with the wireless power receiver such that the first location of the transmission is a location of the wireless power receiver.

Optionally, in a further aspect of the seventh and sixth aspects, the one or more control circuits are configured to determine the relative phase difference and the relative amplitude difference by channel estimation.

Optionally, in the eighth aspect and the further aspects of the third through seventh aspects, the second array of the plurality of antennas is connected to a beamformer, wherein the beamformer is further configured to generate a second plurality of multi-tone power signals and introduce corresponding relative phase differences and relative amplitude differences into each of the second plurality of multi-tone power signals, and wherein each of the antennas in the second array is configured to receive and transmit one of the second plurality of multi-tone power signals.

Optionally, in a ninth aspect and a further aspect of any preceding aspect, the one or more control circuits are connected to the beamformer and configured to determine corresponding delay relative phase differences and relative amplitude differences for a first plurality of multi-tone power signals configured to thereby form a beam at the first location.

Optionally, in the tenth aspect and any preceding further aspect, the frequency center is in a Radio Frequency (RF) range.

Optionally, in the eleventh aspect and any preceding aspect further aspects, the uniform frequency difference is in the range of 10MHz to 50 MHz.

According to another aspect of the disclosure, a method of wireless transmitting power includes generating, by a first wireless power transmitter, a first plurality of copies of a multi-tone power waveform. The method also introduces, by the first wireless power transmitter, a first set of relative delays into the first set of copies of the multi-tone power waveform, the first set of relative delays configured to form a beam when the first set of copies of the multi-tone power waveform is transmitted from the first array of antennas. The method also includes transmitting a first set of copies of the multi-tone power waveform from the first array with a first set of relative delays.

According to another aspect of the present disclosure, a wireless power transfer system includes a first wireless power transmitter and a second wireless power transmitter. The first wireless power transmitter includes: a first signal generation and optimization circuit configured to generate a first plurality of multi-tone beamforming waveforms; and a first antenna array connected to the first signal generation and optimization and configured to receive and transmit the first plurality of multi-tone beamforming waveforms. The second wireless power transmitter includes: a second signal generation and optimization circuit configured to generate a second plurality of multi-tone beamforming waveforms; and a second antenna array connected to the second signal generation and optimization and configured to receive and transmit a second plurality of multi-tone beamforming waveforms. The first and second signal generation and optimization circuits are further configured to generate a first and second plurality of multi-tone beamforming waveforms, respectively, to constructively interfere at a region located between the first and second wireless power transmitters.

This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter. The claimed subject matter is not limited to implementations that solve any or all disadvantages noted in the background.

Drawings

Aspects of the present disclosure are illustrated by way of example and not limitation in the figures of the accompanying drawings.

Fig. 1 illustrates an example wireless battery charging system.

Fig. 2 is a block diagram for one embodiment of a far field wireless power transmitter and a far field wireless power receiver.

Fig. 3A and 3B show simulations of 2D field distributions from an array of 8 antenna elements transmitting RF signals at the same single frequency, equal amplitude, and in phase.

Fig. 4A shows a time domain waveform of an embodiment of a multi-tone signal consisting of 8 equally spaced in-phase tones centered at 2.45GHz with 20MHz spacing between the tones.

Fig. 4B is a diagram showing the fields created by a multi-tone signal at points along the propagation path at different distances from the source at one time instant.

Fig. 5A-5C show two-dimensional simulations of wave propagation from an 8-antenna beamforming transmitter.

Fig. 5D shows the peak field strengths for the same simulations as shown in fig. 5A-5C.

Fig. 6 illustrates an embodiment of transmitting power to a far-field wireless power receiver using two beamforming far-field wireless power transmitters.

Fig. 7A and 7B show 2D simulations of two far-field beamforming wireless power transmitters similar to fig. 5A-5C but with multi-tone power signals used on both sides of the region.

Fig. 7C is the peak field strength for the same simulation as shown in fig. 7A and 7B.

Fig. 7D is a plot of peak field strength for the same simulation of fig. 7C, but where two multi-tone waves of power are transmitted with different delays and beam steering angles to achieve an off-center "hot spot".

Fig. 8 illustrates an environment where strong reflections occur at the boundaries of the domain and in some embodiments reflections from the boundaries may be used to form local "hot spots".

Fig. 9 shows the general case where a domain with a strong reflection boundary (e.g. a room with metal walls) has multiple reflections of the same power signal.

Fig. 10 is a flow diagram of one embodiment of a process for operating a far-field wireless power transmitter using multi-tone power signals.

Fig. 11 is a flow diagram of one embodiment of a process for operating a far-field wireless power transmitter using multi-tone power signals in a multi-subarray or multi-transmitter embodiment as shown in fig. 6.

Fig. 12 and 13 are flow diagrams of embodiments for receiver-initiated and transmitter-initiated channel estimation, respectively.

Detailed Description

The present disclosure will now be described with reference to the accompanying figures, which generally relate to far field wireless power transfer by generating local fields from multi-tone signals using one or more beamforming transmitters.

Far field wireless power transfer is considered a "holy grail" of wireless power technology, as it will enable a Wi-Fi like user experience to power and charge the device. It typically employs a wave, such as an electromagnetic wave (radio frequency or RF and microwave) or a mechanical wave (ultrasonic) to transmit energy from a transmitter to a receiver beyond a few wavelengths (i.e., in the far field). An array of more than one antenna or transducer may be used to "beam" to direct energy from the transmitter to the receiver, thereby exploiting the array gain to overcome path loss. However, a significant drawback of such a typical beamforming method is that when it sends energy from the transmitter to the receiver by generating a field/vibration at the receiver location, it also generates a strong field along the path between the transmitter and the receiver. This field at points along the path is typically stronger than the field at the receiver location, which creates safety and interference issues.

Embodiments are presented below that employ multi-tone signals for power transmission and utilize their time-domain characteristics to locate the strongest field at a specified location in space through strategic placement of wireless power transmitters and optimized beamforming techniques. The frequency spacing, bandwidth, and antenna array size between multi-tone signals may be selected for a particular operating environment to achieve such local fields, which in turn will result in a far-field wireless power transfer solution with significantly less RF exposure and regulatory issues.

Fig. 1 is a block diagram of an example wireless battery charging system 100, which may be used to illustrate some basic elements common in such systems. Referring to fig. 1, an example wireless battery charging system 100 is shown including an adapter 112, a wireless power Transmitter (TX) 122, and a wireless power Receiver (RX) and charger 142. As can be appreciated from fig. 1, the wireless power RX and charger 142 is shown as part of the electronic device 132, the electronic device 132 further including a rechargeable battery 152 and a load 162 powered by the battery 152. Since the electronic device 132 is powered by a battery, the electronic device 132 may also be referred to as a battery powered device 132. Depending on the type of electronic device 132, the load 162 may include, for example, one or more processors, displays, transceivers, and the like. The electronic device 132 may be, for example, a mobile smart phone, a tablet computer, or a notebook computer, but is not limited thereto. The battery 152, e.g., a lithium ion battery, may include one or more electrochemical cells having external connections provided to power a load 162 of the electronic device 132.

The adapter 112 converts an Alternating Current (AC) voltage received from an AC power source 102 into a Direct Current (DC) input voltage (Vin). The AC power source 102 may be provided by a wall outlet or socket or by a generator, but is not limited thereto. The wireless power TX 122 receives an input voltage (Vin) from the adapter 112 and wirelessly transmits power to the wireless power RX and charger 142 according to the input voltage. The wireless power TX 122 may be electrically coupled to the adapter 112 via a cable that includes a plurality of wires, one or more of which may be used to provide an input voltage (Vin) from the adapter 112 to the wireless power TX 122, and one or more of which may provide a communication channel between the adapter 112 and the wireless power TX 122. The communication channel may allow wired two-way communication between the adapter 112 and the wireless power TX 122. The cable that electrically couples the adapter 112 to the wireless power TX 122 may include a ground line that provides a common Ground (GND). The cable between the adapter 112 and the wireless power TX 122 is generally represented in fig. 1 by a double-headed arrow extending between the adapter 112 and the wireless power TX 122. Such a cable may be, for example, a Universal Serial Bus (USB) cable, but is not limited thereto.

The wireless power RX and charger 142 wirelessly receives power from the wireless power TX 122 and charges the battery 152 using the received power. In a typical near-field wireless power transfer system, power transfer between the wireless power RX and charger 142 and the wireless power TX 122 is via inductive coupling of coils on the wireless power RX and charger 142 and the wireless power TX 122. The embodiments discussed below are far field power transmission systems using beamformed wireless power TX 122 and multi-tone RF power signals. The wireless power RX and charger 142 may also be in bidirectional wireless communication with the wireless power supply TX 122. In fig. 1, the double-headed arrows extending between the wireless power TX 122 and the wireless power supply RX and charger 142 are generally used to represent wireless power transfer and communication therebetween.

Fig. 2 is a block diagram for one embodiment of far-field wireless power TX 200 and far-field wireless power RX 250. Considering the receiver first, the illustrated embodiment of far-field wireless power RX 250 includes a power signal receiving antenna 253 connected to a rectifier circuit 257, which in turn is connected to a DC-DC converter 259. According to an embodiment, the antenna 253 is configured to receive an RF waveform that may then be rectified by the rectifier circuit 257 into a DC voltage level to power a storage element 271, such as a battery, drive a load 273, or both. If desired, the DC-DC converter 259 may convert the level of the DC output from the rectifier circuit 257 to supply power to the storage element 271 and the load 273. Many antenna rectification circuit and DC-DC converter designs are known and may be used in the embodiments described herein. The controller 251 is connected to the rectifier circuit 257 and the DC-DC converter 259 to control their operations. In fig. 2, the far-field wireless power receiver 250 also includes a control channel antenna 255, through which the far-field wireless power receiver 250 may exchange control signals with the far-field wireless power transmitter 200, such as may be used to exchange location information and other control data. In the illustrated embodiment, the antenna 255 provides a separate channel for the exchange of control signals, but in other embodiments the control signals may be in-band and encoded in the power signal received at the antenna 253.

On the transmitter side, the far-field wireless power TX 200 comprises a controller 201 connected to a control channel antenna 205, by which control channel antenna 205 the far-field wireless power TX 200 may send and receive control signals exchanged with the far-field wireless power receiver 250. For embodiments using intra-channel switching of control signals, the control signals may be encoded into the power transfer signal. One or more control circuits of the controller 201 are also connected to the power signal generating elements of the far-field wireless power TX 200. Depending on the implementation, the controller 201 may include one or more control circuits and perform the functions described below by hardware, software, firmware, and various combinations of these.

The power signal generating elements of the far-field wireless power Tx 200 include a reference clock source 207, a multi-tone generator 209, a beam former 211, and power amplifiers 213-1 to 213-n. The reference clock source 207 generates a base signal from which the multi-tone generator 209 can generate a multi-tone signal. In fig. 2, reference clock source 207 is shown as generating a lower frequency signal that may then be upconverted to be centered in frequency f of the set of multi-tone signals _C Signals in the RF range of (a), but in other embodiments, the reference clock source 207 may provide another fundamental frequency from which the multi-tone signal is generated, e.g., the frequency center f _C Or the frequency of the lowest tone of a multi-tone signal.

The multi-tone generator 209 receives the fundamental reference clock signal from the reference clock source 207 and generates a multi-tone signal, and in some embodiments, for example, willMulti-tone signal up-conversion to a frequency center f that may be in the RF range _C At or near. As described in more detail below, the frequency difference of the different tone intervals Δ f of the multi-tone power signal, where the value of Δ f may be a fixed value or a variable value that may be determined and provided by one or more controller circuits of the controller 201, depending on the embodiment.

The multi-tone signal from the multi-tone generator 209 is received at the beamformer 211, the beamformer 211 generates multiple copies (n copies in this example) of the multi-tone power signal, and the relative delays or equivalent phases are compared

The replica is introduced and, in some embodiments, the amplitude difference is introduced into the replica. Although represented as separate blocks in fig. 2, multi-tone signal generation and beamforming may be part of a unified process such that, in some embodiments, multi-tone generator 209 may be considered part of beamformer 211. Relative delay or phase->

Determined by one or more control circuits of the controller such that when each of the n signals is transmitted from a corresponding power signal antenna 203-1 to 203-n, they will constructively interfere to form a beam in region 299, and destructively interfere away from region 299. The amplitude and phase may be determined per antenna and per tone. Depending on the implementation, not only may multiple copies of the multi-tone signal have a phase and amplitude distribution, but within each copy of the multi-tone signal, the phase and amplitude of each tone may also differ according to the beamforming algorithm.

For example, the multi-tone power signal may be up-converted to have a frequency center f in the RF range before being provided to the power amplifiers PA 213-1 to PA 213-n _C . In fig. 2, the upconverter is shown as being included as part of the beamformer 211, but in many implementations this will be a separate upconverter block. FromThe respective power signals of the beamformer 211 are here provided by a corresponding one of the power amplifiers PA 213-1 to PA 213-n, wherein the gain g of each power amplifier _i May be determined by the controller 201 and be the same for all beamformed signals or the gain of different signals may be different if the signals have different relative amplitudes. The beamformer 211 (including the upconverter) may be implemented as one or more circuits and in analog, digital, or hybrid implementations by hardware, software, firmware, or various combinations of these. Additionally, although shown as separate blocks in fig. 2, the beamformer 211 may be wholly or partially part of one or more control circuits of the controller 201.

The location of the region 299 may be determined based on control signals exchanged between the far-field wireless power Tx 200 and the far-field wireless power Rx 250. A set of techniques for determining the relative position of far-field wireless power Tx 200 and far-field wireless power Rx 250 and determining beamforming parameters is done by channel estimation, where this may be performed on far-field wireless power Tx 200, far-field wireless power Rx 250, or by a combination of both, depending on the embodiment. The channel estimation process may be performed on the transmitted wireless power signal to initially determine the relative delay or phase

Is initially performed before, but may be updated one or more times to improve the accuracy of the beam.

For embodiments using channel estimation, one or both of channel estimator 202 in far-field wireless power Tx 200 and channel estimator 252 in far-field wireless power Rx 250 may be included, wherein a combination of one or both of channel estimator 202 and channel estimator 252 may be involved in this process. In the far-field wireless power Tx 200 embodiment of fig. 2, a channel estimator 202 is connected between power signal antennas 203-1 to 203-n and a controller 201. Although not shown in fig. 2, a switch bank may be included between channel estimator 202 and power amplifiers PA 213-1 to PA 213-n so that power signal antennas 203-1 to 203-n may be selectively routed to channel estimator 202 or power amplifiers PA 213-1 to PA 213-n. For far-field wireless power Rx 250, a channel estimator 252 is connected between a power signal antenna 253 and the controller 251. Although fig. 2 shows channel estimator 202 and channel estimator 252 as being separate from

respective controllers

201 and 251, in some embodiments the estimators may be part or all of the respective controllers. As with the other elements of far-field wireless power Tx 200 and far-field wireless power Rx 250, channel estimator 202 and channel estimator 252 may be implemented in hardware, software, firmware, or various combinations thereof.

In a first set of embodiments for channel estimation, the far-field wireless power Rx 250 transmits a "beacon" signal through the power signal antenna 253 or, in an alternative embodiment, through the control channel antenna 255. On the far-field wireless power Tx 200 side, each of the power signal antennas 203-1 to 203-n listens for a beacon signal, and based on the received signal, channel estimation is performed between each of the power signal antennas 203-1 to 203-n on the transmitter side and the power signal antenna 253 on the receiver side. Beamforming is then completed for power transmission based on the channel estimation results.

In another set of embodiments for channel estimation, the far-field wireless power Tx 200 may transmit the beacon signal individually from the power signal antennas 203-1 to 203-n one by one. The far-field wireless power Rx 250 continues to listen with the power signal antenna 253 and process the received signal. Channel estimation is performed by the channel estimator 252 on the receiver side. The calculated channel estimation information is transmitted from the far-field wireless power Rx 250 to the far-field wireless power Tx 200 through an in-band channel between the power signal antenna 253 and the power signal antennas 203-1 to 203-n or a control channel between the control channel antenna 255 and the control channel antenna 205. The far-field wireless power Tx 200 may then calculate and apply beamforming parameters to the power transmission.

As discussed above, although far field wireless power transfer is considered a "holy grail" of wireless power technology, a significant drawback of current beamforming methods is that when it sends energy from a transmitter to a receiver by creating a field or vibration at the receiver location, it also creates a strong field along the path between the transmitter and the receiver. This field at locations along the path is typically stronger than the field at the receiver locations, which creates safety and interference issues.

In an RF far-field power transfer embodiment such as that shown in fig. 2, although the field at the region 299 where the power signal receiving antenna 253 of the far-field wireless power Rx 250 is located may not exceed the RF safety (RF exposure) limit, the field strength may be above the limit along the path between the far-field wireless power Tx 200 and the far-field wireless power Rx 250. This can be illustrated by fig. 3A and 3B.

Fig. 3A and 3B show simulations of the 2D field distribution of an array of 8 antenna elements transmitting RF signals at the same single frequency, equal amplitude, and in phase. In each of fig. 3A and 3B, far-field wireless power Tx 300 is located on the left side, and a region 399 for an intended receiver is located at two-thirds of each of the figures. The simulations shown in fig. 3A and 3B are for a beamforming transmitter implementation with an array of 8 antenna elements. In each of fig. 3A and 3B, the horizontal axis is the distance from the transmitter and the vertical axis is the distance to the left or right side of the transmitter, where the units along both axes may be, for example, meters. Fig. 3A shows a wave front propagating from far field wireless power Tx 300 to the left, exhibiting constructive and destructive interference, and where lighter colored regions represent higher field strengths.

The maximum field (as a function of time) for each location is plotted in fig. 3B, where the lighter the color, the stronger the field. As can be seen from fig. 3B, the field closer to the far field wireless power Tx 300 may be much larger than the field strength at the receiver location in region 399, assuming the intended receiver is at the center of the domain at region 399. This phenomenon is one of the key obstacles to far-field wireless power transmission being approved by regulatory agencies, gaining public acceptance, and ultimately providing a good user experience.

One way to alleviate this problem is to define an operating region where the receiver is placed, and to define an exclusion region in the region of highest field values near the transmitter. The system may then employ a motion sensor to detect whether the user is approaching an exclusion zone near the transmitter and turn off power transmission accordingly, which would greatly limit the user experience. As an alternative method, such an embodiment is given below: the time domain nature of the multi-tone signal and the spatial configuration of the transmitter antenna array are exploited to convey beamforming beyond this spatial domain, which better locates the field at the receiver without producing stronger field values between the transmitter and receiver.

More specifically, the embodiments described below employ multi-tone signals for power transmission and utilize the time domain characteristics of such signals to locate the strongest field at a specified location in space through strategic placement of wireless power transmitters and optimized beamforming techniques. The frequency spacing, bandwidth, and antenna array size between multi-tone signals may be strategically selected for a particular operating environment to achieve such local fields, which in turn will result in far-field wireless power transfer solutions with significantly less RF exposure and regulatory issues.

The multi-tone signal can be generally described as:

wherein N is _t Is the number of tones, a _n Is at a frequency f _n The amplitude of the nth tone, and

is the phase of the nth tone. When different tones have the same amplitude (a) _n = constant) and is in phase (= live)>

= constant), a high PAPR (peak to average power ratio) signal is constructed. When the frequencies of the tones are equally spaced apart by the frequency difference Δ f, the expression can be simplified as:

wherein f is _c Is the center frequency of the plurality of tones. As shown in fig. 4A, the multi-tone signal has an envelope following a period of τ =1/Δ f.

FIG. 4A shows a graph consisting of 8 equally spaced lines at f _C Time-domain waveform of an embodiment of a multi-tone signal consisting of in-phase tones centered at =2.45GHz, where the spacing between tones is Δ f =20MHz. As can be seen from fig. 4A, at time 0, all 8 tones are in phase and the amplitude of the combined multi-tone signal is highest (8 x the amplitude of each tone), while over time the 8 tones begin to be out of phase so that the amplitude of the waveform decreases significantly. This continues until τ =1/Δ f (i.e., 50 ns), all tones are again combined in phase and another peak in the field occurs. Essentially, the use of multi-tone signal energy concentrates to periodic peaks every 1/Δ f in the time domain so that the combined field can exceed the turn-on voltage (Vth) of the rectifier diode of the receiver (e.g., rectifier 257 of fig. 2) to deliver power to the load.

In the embodiments presented herein, the field distribution of multi-tone signals in the spatial domain is used to achieve local "hot spots" for power transfer. For example, the same graph as in FIG. 4A may be depicted in the spatial domain, where the x-axis is defined as the distance from the source.

Fig. 4B is a diagram showing fields created by multi-tone signals at points along the propagation path at different distances from the source at one instance in time (attenuation of wave propagation is omitted here for simplicity). As can be seen in fig. 4B, as the multi-tone signal propagates away from the source, it carries time-domain features through space, where each c τ (c represents the speed of light) presents a local peak of the field in space. As these periodic peaks move away from the source, each point along the propagation path is traversed while maintaining the distance between the peaks.

Fig. 5A-5C show 2D simulations of wave propagation for an 8 antenna beamforming transmitter 500 in a 5m x 8m region as the multi-tone signal propagates from the source position to the right, as it carries the time domain characteristics through the domain. The higher field area 510 within the circle is represented in lighter color and propagates to the right as shown in the order of the images.

Fig. 5D shows the peak field strengths for the same simulations as shown in fig. 5A-5C. As shown in the peak field strength plot of fig. 5D, similar to the single frequency case shown in fig. 3B, locations closer to the source still have stronger (lighter in color) field strengths than locations on the propagation path but further from the source. As a result, embodiments that employ only multi-tone signals from a single source in such a configuration may not completely eliminate the transmission/RF exposure problem outlined above. Embodiments presented herein introduce a second transmitter array at a different location not adjacent to the first transmitter array, and which also transmits a multi-tone charging signal to achieve a local intense field value.

Fig. 6 illustrates an embodiment of transmitting power to a far-field wireless power receiver using two beamforming antenna arrays. Depending on the implementation, the two arrays may be two antenna sub-arrays of the same far-field wireless power transmitter, or an antenna array of two independent transmitters. Two arrays or sub-arrays of antennas may carry signals derived from the same clock source to maintain coherence. This is easier to achieve if sub-arrays from the same transmitter are used. When two transmitters are used, the signals from their respective arrays should be derived from the synchronous clock signal by exchanging control signals. Fig. 6 shows an embodiment with two transmitters, but more generally, whether as sub-arrays of a single transmitter or from two separate transmitters, they can be considered as two synchronized antenna arrays.

Considering a two transmitter implementation, two beamforming far field beamformer wireless power transmitter 600 ₁ And 600 ₂ May be as shown in the fig. 3 embodiment of beamformed far-field wireless power TX 300, and includes an array of antennas (603) ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ N) to transmit multi-tone power signals and is arranged to form beams in region 699. For example, in the case of a liquid,in the embodiment used in the 2D simulation shown in fig. 7A to 7D discussed below, n =8, but other values may be used. In general, more antennas provide better defined beams, but at the cost of more power and complexity. Two far field beamforming wireless power transmitters 600 ₁ And 600 ₂ The multi-tone power signals are transmitted such that their beams form in region 699 and constructively interfere to form a "hot spot" in region 699. As mentioned above, although the embodiment of fig. 6 shows two far field beamforming wireless power transmitters 600 ₁ And 600 ₂ Each with its own antenna array (603) ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ N) to transmit multi-tone power signals, but in other embodiments two or more groups of antennas may belong to a single transmitter circuit and be considered as sub-arrays of a larger array, but where the sub-arrays would be placed separately and each sub-array receives a corresponding set of multi-tone power signals for the target area 699.

The far field wireless power receiver 650 is positioned such that the antenna 653 for receiving the multi-tone power signal is located at the "hot spot" of the region 699. The far-field wireless power receiver 650 of fig. 6 may be as described above for the embodiment 250 of fig. 2. Far field wireless power receiver 650 and far field beamforming wireless power transmitter 600 ₁ And 600 ₂ May include respective control channel antennas 655, 605 ₁ And 605 ₂ To exchange information to form a wireless power transmitter 600 upon establishment from a far field beam ₁ And 600 ₂ Is used so that the beams form and constructively interfere in region 699. In one embodiment, wireless power transmitter 600 is beamformed in two far-field beams ₁ And 600 ₂ The control signals exchanged between may be ultrasound signals for maintaining coherence between the two sets of beamforming signals. In other embodiments, some or all of the control signals may be in-band and embedded in the power signal.

FIGS. 7A and 7B illustrate a similar arrangement to that of FIGS. 5A-5C2D simulation, but where two far field beamforming wireless power transmitters 700 on either side of the region ₁ And 700 ₂ Or sub-arrays from the same transmitter transmit multi-tone power signals. As shown in fig. 7A and 7B, two far field beamforming wireless power transmitters 700 ₁ And 700 ₂ Are placed on opposite sides of the 5m x 8m free space domain and the two antenna arrays are synchronized to transmit the same 8 tone signal. Fig. 7A shows the wavefront closer to the antenna, and fig. 7B shows a later time after the multi-tone signal has propagated through the center of the free space domain. The wavefront has the highest field amplitude due to the high PAPR property of the multi-tone signal. As the power signals propagate toward each other, they begin to interfere and produce a local field peak, with the peak produced by the two wavefronts being the strongest. As a result, a local field "hot spot" 799 is generated in space, as also shown in the maximum field plot of fig. 7C.

Fig. 7C is a peak field strength similar to fig. 5D, but for the same simulation as shown in fig. 7A and 7B, with two far field beamforming wireless power transmitters 700 on either side of the region ₁ And 700 ₂ A multi-tone power signal is transmitted. The field strength in the "hot spot" 799 may be optimized so that it is strongest in the domain and even has a higher amplitude than the source antenna position or propagation path between the source and the "hot spot" 799. This phenomenon provides a significant advantage over conventional far-field wireless power transfer solutions by locating the peak of the field in the vicinity of only the wireless power receiver.

The combination of the two beamformed signals and the use of the multi-tone power signal provide a localized "hot spot" 799 at region 797. Wireless power transmitter or sub-array 600 if beamformed from the far field ₁ And 600 ₂ Instead of using the signal tone power signal, the wavefronts continue to travel across each other to continuously interfere with each other along the propagation path. As a result, the field is relatively strong and evenly distributed along the entire propagation path, with a peak field occurring between the source and the intended receiver location. Therefore, the single tone signal does not have the same structure as that of FIG. 7CThe field localization feature is shown.

By using multi-tone signals in such a configuration, local "hot spots" can be achieved almost anywhere in the domain by applying different beam steering and delays between the two transmit arrays. The intended receiver may be off center of both transmitters so that a relative delay may be applied to one of the far field beamformed wireless power transmitters so that a "hot spot" occurs at the intended receiver location. Two far field beamforming wireless power transmitters 600 ₁ And 600 ₂ The different beam steering between the antenna arrays combined with the appropriate relative delay between the two transmitters enables the creation of "hot spots" at arbitrary locations.

Fig. 7D is a plot of peak field strength for the same simulation of fig. 7C, but where two multi-tone waves of power are transmitted with different delays and beam steering angles to achieve an off-center "hot spot" 799. Wireless power transmitter 600 for two far-field beamforming ₁ And 600 ₂ Each of which uses beam steering and introduces a relative delay or equivalently a relative phase between the multi-tone power signals of the two transmitters so that a "hot spot" 799 can be located at a receiver placed at a selected location in the region. By thus using beam steering and relative delays between transmitters, many alternative embodiments are possible in which two or more discontinuous transmitter antenna arrays may be arranged differently than the presently presented examples, e.g. orthogonal, coplanar, etc.

As described above, the combination of a multi-tone signal with a certain frequency separation Δ f between tones and an array configuration enables the generation of local "hot spots" of the wireless power signal, such that the strongest field is generated only in the vicinity of the intended receiver. The rule of thumb for the choice of Δ f is that the corresponding wavelength λ = c/Δ f of the multi-tone signal is larger than the longest dimension of the domain. For example, in the above simulation example, the multi-tone signal has Δ f =20MHz, which corresponds to an equivalent wavelength λ =15m, while the longest dimension of the domain is <10m < λ. When this condition is met, only one "hot spot" is generated in the domain. Otherwise, for the same domain size of 5m × 8m, a multi-tone signal with Δ f =60MHz, for example, would allow more than one time-domain peak to appear in the domain at the same time, which may result in more than one "hot spot". The techniques presented herein are very useful for indoor far-field wireless power transfer to sensors and mobile devices where the average room size is typically small enough to allow only one "hot spot" in the room. They can also be used for simultaneous power and data transmission of a mobile communication base station, for example.

In a real-world implementation of the embodiments presented herein, the domain boundaries may be reflective and there may be obstacles along the signal propagation path. In these cases, the channel is considered an attenuated channel, and in some implementations more complex beamforming techniques may be applied to each antenna and each frequency tone, such that at the intended receiver location, the multi-tone signal may be reconstructed as a combination of multiple reflections. However, as long as the above multi-tone signal and TX antenna configurations are met, a single "hot spot" can be expected in the domain.

Fig. 8 illustrates an environment in which strong reflections occur at the boundaries of a domain and in some embodiments reflections from the boundaries may be used to form local "hot spots". In the example of fig. 8, the right domain with reflective walls is shown, where the 8-element antenna array 800 transmits 8 tone signals towards the right. As the multi-tone wavefront propagates from the antenna array, a multi-tone waveform is observed. Once the wavefront encounters the reflecting boundary on the right, it is reflected back and the reflected signal begins to interfere with the next peak sent from the source toward the right. The interference pattern produces the highest field at position 899 along the propagation path, which is a distance d = c/2 Δ f from the reflecting wall.

This example shows that the technique of creating a local "hot spot" can be implemented with a single continuous antenna array as the source, but where the domain is reflective, so that multiple peaks from the same multi-tone signal transmission can reach the same destination location with different numbers of reflections. The path length distances of the different reflection paths are approximately c/Δ f or integer multiples of c/Δ f. In some embodiments, the controller of the far field power transfer circuit may select the af value as part of the parameter determination in the beamforming process to form a "hot spot" at a desired location.

Fig. 9 shows the general case where a domain with a strong reflection boundary (such as a room with metal walls) has multiple reflections of the same power signal. In some embodiments, the beam may be formed toward a target receiver location, where as the wavefront passes through the target receiver it is reflected back with some attenuation by the reflecting walls. Reflections occur several times in the domain until the wavefront passes again through the target receiver on the third reflection of the same signal. The difference in the distance traveled by the saved signal to reach the target through the direct and multiple reflection paths can be written as:

Δd＝d ₂ +d ₃ +d ₄ +d ₅ 。

when Δ d = c/Δ f or a multiple thereof, an in-phase combination of multiple peaks of the same multi-tone signal will occur. The construction of multi-tone signals can be optimized for fixed source and receiver positions such that the above conditions are met, where a single source array and a strongly reflecting environment can be used to achieve local "hot spots". The use of multi-tone signals provides us with this additional variable Δ f to dynamically adjust for different wireless power transfer environments and scenarios.

Fig. 10 is a flow diagram of one embodiment of a process for operating a far-field wireless power transmitter using multi-tone power signals. Fig. 10 focuses on a single transmitter implementation as shown in fig. 2. Starting at 1001 and referring back to fig. 2, channel estimator 202 and/or channel estimator 252 perform channel estimation by measuring channel parameters between each of power signal antennas 203-1 through 203-n of far-field wireless power TX 200 and power signal antenna 253 of far-field wireless power RX 250. From this channel estimate, the amplitude and phase for beamforming may be determined at 1003 such that the signals from transmit power signal antennas 203-1 through 203-n arrive at the receiver's power signal antenna 253 location in phase on all frequency tones. Using the beamforming parameters determined at 1003, a multi-tone power signal with appropriate phase and amplitude weighting is generated at 1005. More details about 1001 and 1003 are given below with reference to fig. 12 and 13.

The set of beamformed signals are then amplified and transmitted from antenna arrays 203-1 through 203-n at 1007, forming a beam at region 299. At 1009, the far-field wireless RX 250 receives the multi-tone power signal at the antenna 253, which it can use to charge the memory 271, drive the load 273, or both. In some embodiments, at step 1011, the far-field wireless RX 250, the far-field wireless power TX 200, or both may continue to monitor the multi-tone power signal during the power transfer process, if desired, and exchange control signals over the control channel to adjust the beamforming parameters.

Fig. 11 is a flow diagram of one embodiment of a process for operating a far-field wireless power transmitter using multi-tone power signals from an array of multiple transmitter antennas, whether multiple sub-arrays of a single transmitter or in a multiple transmitter embodiment as shown in fig. 6. The process of fig. 11 largely follows the process of fig. 10, but performs channel estimation for multiple transmitter antenna arrays, and if multiple transmitters are used (rather than multiple sub-arrays of a single transmitter), the transmitters will need to coordinate their beamforming so that their individual beams are coherent at the receiver location.

Beginning at 1101 and referring back to fig. 2, a far-field wireless power transmitter 600 ₁ And far field wireless power transmitter 600 ₂ The channel estimator 202 and/or the channel estimator 252 on the channel by measuring the power signal antenna array or sub-array 603 ₁ -1 to 603 ₁ Between each of-n and the power signal antenna 653 of the far-field wireless power RX 650 and the power signal antenna array or sub-array 603 ₂ -1 to 603 ₂ Channel estimation is performed by channel parameters between each of-n and the power signal antenna 653 of the far-field wireless power RX 650. If signal antenna array 603 ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ N belong to different transmitters, rather than sub-arrays of a single transmitter, then at 1103 the transmitters exchange signals to synchronize their clock signals, if this has not been done previously. According toThe channel estimation of 1101 and the synchronization of 1103, at 1105, the amplitude and phase for beamforming may be determined such that the signals from transmit power signal antenna array 603 ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ The signal of-n arrives at the receiver's power signal antenna 653 location in phase on all frequency tones. Using the beamforming parameters determined at 1105, a multi-tone power signal is generated with appropriate phase and amplitude weighting at 1107.

The set of beamformed signals are then amplified at 1109 and transmitted from the antenna 603 ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ N, forming a beam at region 699. At 1111, the far-field wireless RX 650 receives the multi-tone power signal at antenna 653, which can use the signal to charge memory 271, drive load 273, or both. In some embodiments, at step 1113, the far-field wireless receiver and/or far-field wireless power transmitter may continue to monitor the multi-tone power signal during the power transfer process and exchange control signals over the control channel to adjust the beamforming parameters, if desired.

Fig. 12 and 13 are flow diagrams of embodiments for receiver-initiated and transmitter-initiated channel estimation, respectively. In this regard, fig. 12 and 13 provide more detail with respect to 1001 and 1011 of fig. 10 and 1101 and 1113 of fig. 11. The difference between the two cases is that for receiver-initiated beacons, all transmitter antennas can listen and collect data simultaneously to compute the channel estimate, but for transmitter-initiated channel estimates, the transmitter antennas will send beacon signals one by one for the receiver to process the respective channel information.

Beginning at 1201 of fig. 12, a far-field wireless power receiver transmits a beacon signal from its power signal antenna (e.g., 653 or 253). An antenna array or sub-array (203-1 to 203-n, 603) ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ All individual elements of-n) may listen simultaneously, receiving beacons and collecting data at 1203. Based on the received beacon, channel estimation is performed at 1205And (6) counting. Channel estimation may be performed by channel estimator 202. Based on the channel estimates, the controller 201 may determine the beamforming parameters (relative delay/phase, gain/amplitude) used by the beamformer 211 at 1207. Once all the parameters of the multi-tone power signal are set, the power signal may be transmitted. At 1209, far-field wireless power TX 200, 600 ₁ Or 600 ₂ The signal from the far-field wireless power RX 250 or 650 may continue to be monitored by each component of the antenna array or sub-array, where the monitored signal may be a beacon or in-band communication signal. Based on the monitoring, the beamforming parameters may be adjusted at 1211, where this may be a one-time adjustment or a continuous process while continuing to transmit the power signal.

Transmitter initiated channel estimation begins at 1301 where an antenna array or sub-array (203-1 to 203-n, 603) ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ -n) transmits a beacon, which is received at a power signal antenna (e.g., 653 or 253) on the receiver at 1303. 1305 determine if there is a signal from an antenna array or sub-array (203-1 to 203-n, 603) ₁ -1 to 603 ₁ -n and 603 ₂ -1 to 603 ₂ N) and if so, the flow loops back to 1301 for the next beacon. Once all beacons from the transmitters are received, flow continues to 1307 at 1305. At 1307, channel estimation is performed based on the received beacon. Channel estimation may be performed by channel estimator 252. At 1309, the result of the channel estimation may be sent to the far-field wireless power over the control channel. Based on the channel estimation information, at 1311, the controller 201 may determine the beamforming parameters (relative delay/phase, gain/amplitude) used by the beamformer 211. Once all the parameters of the multi-tone power signal are set, the power signal may be transmitted. At 1313, the far-field wireless power RX 250 or 650 may continue to monitor the far-field wireless power TX 200, 600 from each component through the antenna array or sub-array ₁ Or 600 ₂ Of the signal of (1). Based on the monitoring, beamforming parameters may be adjusted 1315, where this may be one-time-useAdjust or continue processing while continuing to transmit the power signal.

Certain implementations of the present technology described herein, such as above, are directed to a controller of a far-field wireless power transmitter (e.g., far-field wireless power TX 200, 600) ₁ Or 600 ₂ Controller 201) or a controller on the far-field wireless power receiver (e.g., controller 251 of far-field wireless power RX 250 or 650) may be implemented using hardware, software, or a combination of both hardware and software. The software used may be stored on one or more of the above-described processor-readable storage devices to program one or more processors to perform the functions described herein. Processor-readable storage can include computer-readable media such as volatile and nonvolatile media, removable and non-removable media. By way of example, and not limitation, computer-readable media may comprise computer-readable storage media and communication media. Computer-readable storage media may be implemented in any method or technology for storage of information such as computer-readable instructions, data structures, program modules or other data. Examples of computer readable storage media include RAM, ROM, EEPROM, flash memory or other memory technology, CD-ROM, digital Versatile Disks (DVD) or other optical disk storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium which can be used to store the desired information and which can be accessed by a computer. A computer readable medium (medium) or media (media) does not include propagated, modulated, or transitory signals.

Communication media typically embodies computer readable instructions, data structures, program modules or other data in a propagated, modulated or transitory data signal such as a carrier wave or other transport mechanism and includes any information delivery media. The term "modulated data signal" means a signal that has one or more of its characteristics set or changed in such a manner as to encode information in the signal. By way of example, and not limitation, communication media includes wired media such as a wired network or connection, and wireless media such as RF and other wireless media. Combinations of any of the above are also included within the scope of computer readable media.

In alternative embodiments, some or all of the software may be replaced by dedicated hardware logic components. By way of example, and not limitation, exemplary types of hardware Logic components that may be used include Field-Programmable Gate arrays (FPGAs), application-specific Integrated circuits (ASICs), application-specific Standard products (ASSPs), system-on-a-chip systems (socs), complex Programmable Logic Devices (CPLDs), dedicated computers, and the like. In one embodiment, software (stored on a storage device) implementing one or more embodiments is used to program one or more processors. The one or more processors may communicate with one or more computer-readable media/storage devices, peripherals, and/or communication interfaces.

It should be understood that the present subject matter may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this subject matter is thorough and complete, and will fully convey the disclosure to those skilled in the art. Indeed, the present subject matter is intended to cover alternatives, modifications and equivalents of these embodiments, which are included within the scope and spirit of the subject matter as defined by the appended claims. Furthermore, in the detailed description of the present subject matter, numerous specific details are set forth in order to provide a thorough understanding of the present subject matter. It will be apparent, however, to one of ordinary skill in the art that the present subject matter may be practiced without these specific details.

Aspects of the present disclosure are described herein with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems) and computer program products according to embodiments of the disclosure. It will be understood that each block of the flowchart illustrations and/or block diagrams, and combinations of blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a mechanism, such that the instructions, which execute via the processor of the computer or other programmable instruction execution apparatus, create means for implementing the functions/acts specified in the flowchart and/or block diagram block or blocks.

The description of the present disclosure has been presented for purposes of illustration and description, but is not intended to be exhaustive or limited to the disclosure in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the disclosure. The aspects of the disclosure were chosen and described in order to best explain the principles of the disclosure and the practical application, and to enable others of ordinary skill in the art to understand the disclosure for various modifications as are suited to the particular use contemplated.

The present disclosure has been described in connection with various embodiments. However, other variations and modifications to the disclosed embodiments can be understood and effected by studying the drawings, the disclosure and the appended claims, and these variations and modifications are to be construed as being included in the appended claims. In the claims, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality.

For the purposes of this document, it should be noted that the dimensions of the various features depicted in the drawings may not necessarily be drawn to scale.

For the purposes of this document, references in the specification to "an embodiment," "one embodiment," "some embodiments," or "another embodiment" may be used to describe different embodiments or the same embodiments.

For purposes of this document, a connection may be a direct connection or an indirect connection (e.g., indirectly via one or more other components). In some cases, when an element is referred to as being connected or coupled to another element, it can be directly connected to the other element or be indirectly connected to the other element via an intervening element. When an element is referred to as being directly connected to another element, there are no intervening elements present between the element and the other element. Two devices "communicate" if they are connected, directly or indirectly, such that they can transmit electronic signals between the two.

For purposes of this document, the term "based on" may be read as "based, at least in part, on".

For purposes of this document, the use of quantitative terms such as "first" object, "second" object, and "third" object may not imply an order of the objects, but may instead be used for identification purposes to identify different objects, without additional context.

The foregoing detailed description has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the subject matter claimed herein to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. The described embodiments were chosen in order to best explain the principles of the disclosed technology and its practical application to thereby enable others skilled in the art to utilize the technology in various embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope be defined by the following claims.

Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.

Claims

1. A wireless power transmitter, comprising:

a beamformer configured to generate a multi-tone power signal formed by a plurality of tones having frequency centers and spaced by a uniform frequency difference and to generate a first plurality of multi-tone power signals from the multi-tone power signal, the first plurality of multi-tone power signals configured to form a beam at a first location;

a first array of multiple antennas connected to the beamformer, each of the antennas in the first array configured to receive and transmit one of the first plurality of multi-tone power signals;

a second array of multiple antennas connected to the beamformer, wherein the beamformer is further configured to generate a second plurality of multi-tone power signals and introduce corresponding relative phase differences and relative amplitude differences into each of the second plurality of multi-tone power signals,

wherein each of the first plurality of multi-tone power signals has a corresponding relative phase difference configured to form a beam at the first location,

each of the first plurality of multi-tone power signals having a corresponding relative amplitude difference configured to form a beam at the first location,

each of the antennas in the second array is configured to receive and transmit one of the second plurality of multi-tone power signals.

2. The wireless power transmitter of claim 1, further comprising:

one or more control circuits connected to the beamformer and configured to determine corresponding relative phase differences and relative amplitude differences for the first plurality of multi-tone power signals.

3. The wireless power transmitter of claim 2, further comprising:

a communication antenna connected to the one or more control circuits, the one or more control circuits further configured to exchange signals with a wireless power receiver through the communication antenna and determine corresponding relative phase differences and relative amplitude differences for the first plurality of multi-tone power signals based on the signals exchanged with the wireless power receiver.

4. The wireless power transmitter of claim 3, wherein the one or more control circuits are further configured to determine corresponding relative phase differences and relative amplitude differences based on signals exchanged with the wireless power receiver such that the first location is a location of the wireless power receiver.

5. The wireless power transmitter of claim 4, wherein the one or more control circuits are configured to determine a relative phase difference and a relative amplitude difference by channel estimation.

6. The wireless power transmitter of any of claims 1-5, further comprising:

one or more control circuits connected to the beamformer and configured to determine corresponding delay relative phase differences and relative amplitude differences for the first plurality of multi-tone power signals configured to thereby form a beam at a first location.

7. The wireless power transmitter of any of claims 1-5, wherein the frequency center is in a Radio Frequency (RF) range.

8. The wireless power transmitter of any of claims 1-5, wherein the uniform frequency difference is in a range of 10MHz to 50 MHz.

9. A method of wirelessly transmitting power, comprising:

generating, by a first wireless power transmitter, a first plurality of copies of a multi-tone power waveform;

introducing, by the first wireless power transmitter, a first set of relative delays into a first set of copies of the multi-tone power waveform, the first set of relative delays configured to form a beam when the first set of copies of the multi-tone power waveform is transmitted from a first array of antennas; and

transmitting the first set of copies of the multi-tone power waveform with the first set of relative delays from a first array;

the method further comprises the following steps:

introducing, by the first wireless power transmitter, a first set of relative amplitude differences into the first set of copies of the multi-tone power waveform, the first set of relative amplitude differences configured to form a beam when the first set of copies of the multi-tone power waveform is transmitted from a first array of antennas,

wherein generating the first plurality of copies of the multi-tone power waveform comprises:

generating a multi-tone power waveform having a plurality of tones, the plurality of tones having frequency centers and being spaced apart by a uniform frequency difference; and

replicating the multi-tone power waveform to generate the first plurality of replicas of the multi-tone power waveform,

the method further comprises the following steps:

generating a second plurality of copies of the multi-tone power waveform;

introducing, by a second wireless power transmitter, a second set of relative delays into a second set of copies of the multi-tone power waveform, the second set of relative delays configured to form beams when the second set of copies of the multi-tone power waveform are transmitted from a second array of antennas, wherein the first set of relative delays and the second set of relative delays are configured such that beams formed by the second set of copies of the multi-tone power waveform when transmitted from the second array of antennas are formed in the same region and constructively interfere with beams formed by the first set of copies of the multi-tone power waveform when transmitted from the first array of antennas;

transmitting the second set of copies of the multi-tone power waveform with the second set of relative delays from a second array.

10. The method of claim 9, further comprising:

exchanging signals between the first wireless power transmitter and a wireless power receiver; and

determining the first set of relative delays and relative amplitude differences based on the exchanged signals to form a beam at the location of the wireless power receiver.

11. The method of claim 10, wherein determining the first set of relative delays and relative amplitude differences based on the exchanged signals comprises:

performing, by the first wireless power transmitter, channel estimation.

12. The method of claim 10, wherein determining the first set of relative delays and relative amplitude differences based on the exchanged signals comprises:

performing channel estimation by the wireless power receiver.

13. The method of any of claims 9-12, wherein the multi-tone power waveform comprises a plurality of tones spaced by a uniform frequency difference, and further comprising:

changing the uniform frequency difference.

14. A wireless power transfer system, comprising:

a first wireless power transmitter, comprising:

a first signal generation and optimization circuit configured to generate a first plurality of multi-tone beamformed waveforms, wherein the first signal generation and optimization circuit comprises a first beamformer configured to introduce a corresponding first delay into each of the first plurality of multi-tone beamformed waveforms; and

a first antenna array connected to the first signal generation and optimization and configured to receive and transmit the first plurality of multi-tone beamforming waveforms; and

a second wireless power transmitter, comprising:

second signal generation and optimization circuitry configured to generate a second plurality of multi-tone beamformed waveforms, wherein the second signal generation and optimization circuitry comprises a first beamformer configured to introduce a corresponding second delay into each of the second plurality of multi-tone beamformed waveforms; and

a second antenna array connected to the second signal generation and optimization and configured to receive and transmit the second plurality of multi-tone beamforming waveforms,

wherein the first and second signal generation and optimization circuits are further configured to generate the first and second pluralities of multi-tone beamforming waveforms, respectively, to constructively interfere at a region located between the first and second wireless power transmitters.

15. The wireless power transfer system of claim 14, wherein the first wireless power transmitter further comprises:

one or more first control circuits connected to the first signal generation and optimization circuit; and

a first communication antenna connected to the one or more first control circuits; and is

Wherein the second wireless power transmitter further comprises:

one or more second control circuits connected to the second signal generation and optimization circuit; and

a second communication antenna connected to the one or more second control circuits,

wherein the one or more first control circuits and the one or more second control circuits are configured to exchange signals with a wireless power receiver through the first communication antenna and the second communication antenna, respectively, and to determine corresponding first and second delays based on the signals exchanged with the wireless power receiver such that an area located between the first wireless power transmitter and the second wireless power transmitter corresponds to a location of the wireless power receiver.

16. The wireless power transfer system of claim 15, wherein one or both of the one or more first control circuits and the one or more second control circuits are configured to determine the first delay through channel estimation.